Concepts+of+Modern+Physics+Solutions

Chapter 1. Problem Solutions 1. If the speed of light were smaller than it is, would relativistic phenomena be more or

Views 573 Downloads 95 File size 2MB

Report DMCA / Copyright

DOWNLOAD FILE

Citation preview

Chapter 1. Problem Solutions 1.

If the speed of light were smaller than it is, would relativistic phenomena be more or less conspicuous than they are now?

Sol All else being the same, including the rates of the chemical reactions that govern our brains and bodies, relativisitic phenomena would be more conspicuous if the speed of light were smaller. If we could attain the absolute speeds obtainable to us in the universe as it is, but with the speed of light being smaller, we would be able to move at speeds that would correspond to larger fractions of the speed of light, and in such instances relativistic effects would be more conspicuous.

3.

An athlete has learned enough physics to know that if he measures from the earth a time interval on a moving spacecraft, what he finds will be greater than what somebody on the spacecraft would measure. He therefore proposes to set a world record for the 100-m dash by having his time taken by an observer on a moving spacecraft. Is this a good idea?

Sol Even if the judges would allow it, the observers in the moving spaceship would measure a longer time, since they would see the runners being timed by clocks that appear to run slowly compared to the ship's clocks. Actually, when the effects of length contraction are included (discussed in Section 1.4 and Appendix 1), the runner's speed may be greater than, less than, or the same as that measured by an observer on the ground.

Inha University

Department of Physics

5.

Two observers, A on earth and B in a spacecraft whose speed is 2.00 x 108 m/s, both set their watches to the same time when the ship is abreast of the earth. (a) How much time must elapse by A's reckoning before the watches differ by 1.00 s? (b) To A, B's watch seems to run slow. To B, does A's watch seem to run fast, run slow, or keep the same time as his own watch?

Sol Note that the nonrelativistic approximation is not valid, as v/c = 2/3. (a) See Example 1.1. In Equation (1.3), with t representing both the time measured by A and the time as measured in A's frame for the clock in B's frame to advance by to, we need 2  2    v 2     t t0 t 1 1 t 2  1 1  t 0.255 1.00 s c     from which t = 3.93 s. 3     (b) A moving clock always seems to run slower. In this problem, the time t is the time that observer A measures as the time that B's clock takes to record a time change of to.

Inha University

Department of Physics

7.

How fast must a spacecraft travel relative to the earth for each day on the spacecraft to correspond to 2 d on the earth?

Sol From Equation (1.3), for the time t on the earth to correspond to twice the time t0 elapsed on the ship’s clock, 2

1 v 2  1, so v c 2 2 relating three significant figures. 9.

3 c2.60108 m/s,

A certain particle has a lifetime of 1.00 x10-7 s when measured at rest. How far does it go before decaying if its speed is 0.99c when it is created?

Sol The lifetime of the particle is t0, and the distance the particle will travel is, from Equation (1.3), vt 

vt0 2

2

1v /c to two significant figures.

Inha University



(0.99)(3.0

8

10 m/s)(1.0010 1(0.99)

2

7

s)

210 m

Department of Physics

11. A galaxy in the constellation Ursa Major is receding from the earth at 15,000 km/s. If one of the characteristic wavelengths of the light the galaxy emits is 550 nm, what is the corresponding wavelength measured by astronomers on the earth? Sol See Example 1.3; for the intermediate calculations, note that



c o 1v/c  o ,  o  1v/c c

where the sign convention for v is that of Equation (1.8), which v positive for an approaching source and v negative for a receding source. For this problem, v 1 50107 km/s  0 050, c 30 108 m/s

so that

o

1v/c 1v/c

Inha University

(550 nm)

10.050 1 0.050

578 nm

Department of Physics

13. A spacecraft receding from the earth emits radio waves at a constant frequency of 109 Hz. If the receiver on earth can measure frequencies to the nearest hertz, at what spacecraft speed can the difference between the relativistic and classical Doppler effects be detected? For the classical effect, assume the earth is stationary. Sol This problem may be done in several ways, all of which need to use the fact that when the frequencies due to the classical and relativistic effects are found, those frequencies, while differing by 1 Hz, will both be sufficiently close to vo = 109 Hz so that vo could be used for an approximation to either. In Equation (1.4), we have v = 0 and V = -u, where u is the speed of the spacecraft, moving away from the earth (V < 0). In Equation (1.6), we have v = u (or v = -u in Equation (1.8)). The classical and relativistic frequencies, vc and vr respectively, are c 

0

r o

1(u c)

2

1(u

c)

o 1(u c) 1(u c) 1(u c) The last expression for vo, is motivated by the derivation of Equation (1.6), which essentially incorporates the classical result (counting the number of ticks), and allows expression of the ratio ,

c 1  r  1(u c)2

Inha University

Department of Physics

Use of the above forms for the frequencies allows the calculation of the ratio 2

   1 1(u c) 1 Hz c r 9     10 o 9  1(u c) 10 Hz o Attempts to solve this equation exactly are not likely to be met with success, and even numerical solutions would require a higher precision than is commonly available. However, recognizing that the numerator 1 1(u/c) 2is of the form that can be approximated using the methods outlined 2

2

at the beginning of this chapter, we can use 1 1(u/c)  (1/2)(u /c ) . The denominator will be indistinguishable from 1 at low speed, with the result

1u which is solved for

2c 9

2

9

2

10 ,

u  210 c 1.34104m/s13.4 km/s

Inha University

Department of Physics

15. If the angle between the direction of motion of a light source of frequency v o and the direction from it to an observer is 0, the frequency v the observer finds is given by o

2

2

1v /c 1( v c)cos where v is the relative speed of the source. Show that this formula includes Eqs. (1.5) to (1.7) as special cases. Sol The transverse Doppler effect corresponds to a direction of motion of the light source that is perpendicular to the direction from it to the observer; the angle  = /2 (or 90o), so cos = 0, 2

2

(1.5). and o 1v /c , which is Equation o For a receding source,  =  (or 180 ), and cos = 1. The given expression becomes o

2

1v /c

2

1v/c

1v/c o , 1v/c

which is Equation (1.8). For an approaching source,  = 0, cos = 1, and the given expression becomes o

2

1v /c 1v/c

2

1v/c o , 1v/c

which is Equation (1.8).

Inha University

Department of Physics

17. An astronaut whose height on the earth is exactly 6 ft is lying parallel to the axis of a spacecraft moving at 0.90c relative to the earth. What is his height as measured by an observer in the same spacecraft? By an observer on the earth? Sol The astronaut’s proper length (height) is 6 ft, and this is what any observer in the spacecraft will measure. From Equation (1.9), an observer on the earth would measure LL

2 o

2

1v /c

2

(6 ft) 1 ( .90)  2.6 ft

19. How much time does a meter stick moving at 0.100c relative to an observer take to pass the observer? The meter stick is parallel to its direction of motion. Sol The time will be the length as measured by the observer divided by the speed, or 2

2

2

(1.00 m) 1(0.100) 3.3210 8 s t  L Lo 1v /c   (0.100)(3.0 108 m/s) v v

Inha University

Department of Physics

21. A spacecraft antenna is at an angle of 10 o relative to the axis of the spacecraft. If the spacecraft moves away from the earth at a speed of 0.70c, what is the angle of the antenna as seen from the earth? Sol If the antenna has a length L' as measured by an observer on the spacecraft (L' is not either L or LO in Equation (1.9)), the projection of the antenna onto the spacecraft will have a length L'cos(10o), and the projection onto an axis perpendicular to the spacecraft's axis will have a length L'sin(10o). To an observer on the earth, the length in the direction of the spacecraft's axis will be contracted as described by Equation (1.9), while the length perpendicular to the spacecraft's motion will appear unchanged. The angle as seen from the earth will then be

 arctan



o

Lsin(10 ) o

2

2

Lcos(10 ) 1v /c



arctan

tan(10 )



1(0 70)





o

2

o

14 

The generalization of the above is that if the angle is 00 as measured by an observer on the spacecraft, an observer on the earth would measure an angle  given by tan

tano 2

1v /c

Inha University

2

Department of Physics

23. A woman leaves the earth in a spacecraft that makes a round trip to the nearest star, 4 lightyears distant, at a speed of 0.9c. Sol The age difference will be the difference in the times that each measures the round trip to take, or Lo

2

4 yr

2 1 1092. 5 yr. v 0.9 25. All definitions are arbitrary, but some are more useful than others. What is the objection to defining linear momentum as p = mv instead of the more complicated p = mv? Sol It is convenient to maintain the relationship from Newtonian mechanics, in that a force on an object changes the object's momentum; symbolically, F = dp/dt should still be valid. In the absence of forces, momentum should be conserved in any inertial frame, and the conserved quantity is p = -mv, not mv t 2

11v

/c

2

27. Dynamite liberates about 5.4 x 10 6 J/kg when it explodes. What fraction of its total energy content is this? Sol For a given mass M, the ratio of the mass liberated to the mass energy is 6

11 M (5410 J/kg) 8 2 6010 M (3010 m/s)

Inha University

Department of Physics

29.

At what speed does the kinetic energy of a particle equal its rest energy?

Sol If the kinetic energy K = Eo = mc2, then E = 2mc2 and Equation (1.23) reduces to 1 2 2 2 1v /c ( = 2 in the notation of Section 1.7). Solving for v, 3 8 v c 2.60 10 m/s 2 31. An electron has a kinetic energy of 0.100 MeV. Find its speed according to classical and relativistic mechanics. Sol Classically, v 

19

2K



2 0.200MeV 1.60 10 31

J/eV

9.1110 me kg Relativistically, solving Equation (1.23) for v as a function of K, 2

mec 2   mec 2 v c 1  c 1    2  E  mec K

Inha University

2

1.88 108 m/s. 2

  1  c 1   2   1 K /(mec )

Department of Physics

With K/(mec2) = (0.100 MeV)/(0.511 MeV) = 0.100/0.511, 2

 1  1.64 108 m/s. m/s  1   1(0.100)/(0.511) The two speeds are comparable, but not the same; for larger values of the ratio of the kinetic and rest energies, larger discrepancies would be found. v 3.0 10

33.

8

A particle has a kinetic energy 20 times its rest energy. Find the speed of the particle in terms of c.

Sol Using Equation (1.22) in Equation (1.23) and solving for v/c, 2

v  1 Eo    c E  With E = 21Eo, that is, E = Eo + 20Eo, 2

v c 1 1   0.9989c. 21  

Inha University

Department of Physics

35. How much work (in MeV) must be done to increase the speed of an electron from 1.2 x 10 8 m/s to 2.4 X 108 m/s? Sol The difference in energies will be, from Equation (1.23), me c







1 1    2 2 2 2  1v 2 /c 1v1 /c    1 1  (0.511MeV) 0.294 MeV  2 2  1( .24 / .0) 1(1.2 / .0)   2

37. Prove that ½mv2, does not equal the kinetic energy of a particle moving at relativistic speeds. Sol Using the expression in Equation (1.20) for the kinetic energy, the ratio of the two quantities is 1 2 2 mv

K

2 1v2   1 v   2 2 2   1  c  2 c

 

  1   1 2 2  1v /c 

Inha University

Department of Physics

39. An alternative derivation of the mass-energy formula EO = mc2, also given by Einstein, is based on the principle that the location of the center of mass (CM) of an isolated system cannot be changed by any process that occurs inside the system. Figure 1.27 shows a rigid box of length L that rests on a frictionless surface; the mass M of the box is equally divided between its two ends. A burst of electromagnetic radiation of energy Eo is emitted by one end of the box. According to classical physics, the radiation has the momentum p = Eo/c, and when it is emitted, the box recoils with the speed v E01Mc so that the total momentum of the system remains zero. After a time t L/c the radiation reaches the other end of the box and is absorbed there, which brings the box to a stop after having moved the distance S. If the CM of the box is to remain in its original place, the radiation must have transferred mass from one end to the other. Show that this amount of mass is m = EO 1c2. Sol Measured from the original center of the box, so that the original position of the center of mass is 0, the final position of the center of mass is M L  M L    m S  m  S0. 2  2   2  2  Expanding the products and canceling similar terms [(M/2)(L/2), mS], the result MS = mL is obtained. The distance 5 is the product vt, where, as shown in the problem statement, v E/Mc (approximate in thenonrelativistic limit M >> Elc2) and t  L/c. Then, MS M E L E m   L L Mc c c2

Inha University

Department of Physics

41. In its own frame of reference, a proton takes 5 min to cross the Milky Way galaxy, which is about 105 light-years in diameter. (a) What is the approximate energy of the proton in electronvolts?. (b) About how long would the proton take to cross the galaxy as measured by an observer in the galaxy's reference frame? Sol To cross the galaxy in a matter of minutes, the proton must be highly relativistic, with v c (but v < c, of course). The energy of the proton will be E = Eo, where EO is the proton's rest energy 2

2

and 1/ 1v /c . However, , from Equation (1.9), is the same as the ratio LO/L, where L is the diameter of the galaxy in the proton's frame of reference, and for the highly-relativistic proton L  ct, where t is the time in the proton's frame that it takes to cross the galaxy. Combining, E  Eo  E

L o

o

E

L o

5 o

9

(10 eV)

10 ly

7

19

(310 s/yr ) 10

L ct c(300 s) 43. Find the momentum (in MeV/c) of an electron whose speed is 0.600c. Sol Taking magnitudes in Equation (1.16), p 

2

m ev 2

1v2/c

Inha University

eV



(0 511 MeV /c )(0 600c) 2

 0 383 MeV/c

1(0 600)

Department of Physics

45. Find the momentum of an electron whose kinetic energy equals its rest energy of 511 keV Sol When the kinetic energy of an electron is equal to its rest energy, the total energy is twice the rest energy, and Equation (1.24) becomes 4m4c4m4c4p2c

2

,

or

p  3(mec2)/c

 3(511 keV /c) 1.94 GeV /c

The result of Problem 1-29 could be used directly;  = 2, v = ( p= m3c, as above. 47.

/23c, and Equation (1.17) gives

Find the speed and momentum (in GeV/c) of a proton whose total energy is 3.500 GeV

Sol Solving Equation (1.23) for the speed v in terms of the rest energy EO and the total energy E, v c 1(Eo/E)c 1(0.938/ .500)

2

 0.963c

numerically 2.888 x 108 m/s. (The result of Problem 1-32 does not give an answer accurate to three significant figures.) The value of the speed may be substituted into Equation (1.16) (or the result of Problem 1-46), or Equation (1.24) may be solved for the magnitude of the momentum, 2

2

2

p (E/c)2(Eo/c)  (3.500 GeV/c) (0.938 GeV/c) 3.37 GeV/c

Inha University

Department of Physics

49. A particle has a kinetic energy of 62 MeV and a momentum of 335 MeV/c. Find its mass (in MeV/c2) and speed (as a fraction of c). Sol From E = mc2 + K and Equation (1.24), 2 2 4 2 2  mc2 K  m c p c

Expanding the binomial, cancelling the m2c4 term, and solving for m, 2

m  (pc) 2K 2c K

2

2



(335MeV) (62MeV)

2

874 MeV/c

2

2

2c (62 MeV) The particle's speed may be found any number of ways; a very convenient result is that of Problem 1-46, giving pc 335 MeV 2 p c 0 36c. c v c E 874MeV 62MeV mc2K

Inha University

Department of Physics

51. An observer detects two explosions, one that occurs near her at a certain time and another that occurs 2.00 ms later 100 km away. Another observer finds that the two explosions occur at the, same place. What time interval separates the explosions to the second observer? Sol The given observation that the two explosions occur at the same place to the second observer means that x' = 0 in Equation (1.41), and so the second observer is moving at a speed 5

v  x 1.0010 m 5.00107 m/s 3  2.0010 s t

with respect to the first observer. Inserting this into Equation (1.44), 2

t

t  x 2 tc

2

t

1

x

2

2 2

t 1

c t 2

(x t)

1(x /ct) 1x /c t2 c 7 2 (2.00ms) 1 (5.00 10 m/s) 1.97 ms. 8 2 (2.99810 m/s) 2

2

2

2

(For this calculation, the approximation 1(x/ct) 1(x /2c t2)valid to three significant figures.) An equally valid method, and a good cheek, is to note that when the relative speed of the observers (5.00 x 107 m/s) has been determined, the time interval that the second observer measures should be that given by Equation (1.3) (but be careful of which time it t, which is to). Algebraically and numerically, the different methods give the same result.

Inha University

Department of Physics

53. A spacecraft moving in the +x direction receives a light signal from a source in the xy plane. In the reference frame of the fixed stars, the speed of the spacecraft is v and the signal arrives at an angle  to the axis of the spacecraft. (a) With the help of the Lorentz transformation find the angle  ' at which the signal arrives in the reference frame of the spacecraft. (b) What would you conclude from this result about the view of the stars from a porthole on the side of the spacecraft? Sol (a) A convenient choice for the origins of both the unprimed and primed coordinate systems is the point, in both space and time, where the ship receives the signal. Then, in the unprimed frame (given here as the frame of the fixed stars, one of which may be the source), the signal was sent at a time t = -r/c, where r is the distance from the source to the place where the ship receives the signal, and the minus sign merely indicates that the signal was sent before it was received. Take the direction of the ship's motion (assumed parallel to its axis) to be the positive x-direction, so that in the frame of the fixed stars (the unprimed frame), the signal arrives at an angle 0 with respect to the positive x-direction. In the unprimed frame, x = r cos and y = r sin  . From Equation (1.41),

x

x vt 2

1v /c

and y’= y = r sin . Then,

Inha University

2



r cos(r c) 2

1v /c

2

r

cos(v c) 2

1v /c

2

,

Department of Physics

y tan   x  (cos(

       

sin 2

1v /c v

2

   ,

and

 2 2  sin 1v /c arctan  cos(v c)  

c))/ (b) From the form of the result of part (a), it can be seen that the numerator of the term in square brackets is less than sin , and the denominator is greater than cos , and so tan  and ’ <  when v0. Looking out of a porthole, the sources, including the stars,will appear to be in the directions close to the direction of the ship’s motion than they would for a ship with v = 0. As vc, ’0, and all stars appear to be almost on the ship’s axis(farther forward in the field of view). 55. A man on the moon sees two spacecraft, A and B, coming toward him from opposite directions at the respective speeds of 0.800c and 0.900c. (a) What does a man on A measure for the speed with which he is approaching the moon? For the speed with which he is approaching B? (b) What does a man on B measure for the speed with which he is approaching the moon? For the speed with which he is approaching A ? Sol (a) If the man on the moon sees A approaching with speed v = 0.800 c, then the observer on A will see the man in the moon approaching with speed v = 0.800c. The relative velocities will have opposite directions, but the relative speeds will be the same. The speed with which B is seen to approach A, to an observer in A, is then Vv 0 800 0 900 Vx  2 c 0 988c 1vV x /c 1(0 800)(0 900)

Inha University

Department of Physics

(b) Similarly, the observer on B will see the man on the moon approaching with speed 0.900 c, and the apparent speed of A, to an observer on B, will be

0 9000 800 c 0 988c 1(0 900)(0 800) (Note that Equation (1.49) is unchanged if Vx’ and v are interchanged.) S’(moon)

B Vx’

Inha University

v

S

A

O’

Department of Physics

Chapter 2 Problem Solutions 1.

If Planck's constant were smaller than it is, would quantum phenomena be more or less conspicuous than they are now?

Sol Planck’s constant gives a measure of the energy at which quantum effects are observed. If Planck’s constant had a smaller value, while all other physical quantities, such as the speed of light, remained the same, quantum effects would be seen for phenomena that occur at higher frequencies or shorter wavelengths. That is, quantum phenomena would be less conspicuous than they are now.

Is it correct to say that the maximum photoelectron energy KEmax is proportional to the frequency  of the incident light? If not, what would a correct statement of the relationship between KEmax and  be? Sol No: the relation is given in Equation (2.8) and Equation (2.9),

3.

 h h( ),

KE max

o

So that while KEmax is a linear function of the frequency  of the incident light, KEmax is not proportional to the frequency.

Inha University

Department of Physics

5. Find the energy of a 700-nm photon. Sol From Equation (2.11), 1.2410 6eV m E  1.77 eV. -9 70010 m Or, in terms of joules, E



(6.63 10

34

Js)(3.0 108 m/s) 9

2.8410

19

J

700 10 m 7. A 1.00-kW radio transmitter operates at a frequency of 880 kHz. How many photons per second does it emit? Sol The number of photons per unit time is the total energy per unit time(the power) divided by the energy per photon, or P P 1.00103 J/s 30   1.7210 photons/s . E h ( .63 10 34 Js)(880 103Hz)

Inha University

Department of Physics

Light from the sun arrives at the earth, an average of 1.5 x 1011 m away, at the rate of 1.4 x 103 W/m2 of area perpendicular to the direction of the light. Assume that sunlight is monochromatic with a frequency of 5.0 x 1014 Hz. (a) How many photons fall per second on each square meter of the earth's surface directly facing the sun? (b) What is the power output of the sun, and how many photons per second does it emit? (c) How many photons per cubic meter are there near the earth? Sol (a) The number of photons per unit time per unit are will be the energy per unit time per unit area (the power per unit area, P/A), divided by the energy per photon, or

9.

3

P /A

2

21 2 1410 W/m  4210 photons/(s m ). -34 14 h (6.6310 Js)(5.010 Hz)

(b) With the reasonable assumption that the sun radiates uniformly in all directions, all points at the same distance from the sun should have the same flux of energy, even if there is no surface to absorb the energy. The total power is then, 2

11

2

26

(P /A)4RES (1.4 103W/m2)4(1.5 10 m) 4.0 10 W, where RE-S is the mean Earth-Sun distance, commonly abbreviated as “1 AU,” for “astronomical unit.” The number of photons emitted per second is this power divided by the energy per photon, or .40 10

(6.6310

Inha University

-34

26

J/s

1.2 10

14

Js)(5.0 10

45

photons/s .

Hz)

Department of Physics

(c) The photons are all moving at the same speed c, and in the same direction (spreading is not significant on the scale of the earth), and so the number of photons per unit time per unit area is the product of the number per unit volume and the speed. Using the result from part (a), 21

2

13 4210 photons/(s m ) 1410 photons/m 8 3010 m/s

3

11. The maximum wavelength for photoelectric emission in tungsten is 230 nm. What wavelength of light must be used in order for electrons with a maximum energy of 1.5 eV to be ejected? Sol Expressing Equation (2.9) in terms of  = c/ and 0 = c/0, and performing the needed algebraic manipulations, 

hc (hc /)  K o

 (230nm)1  

1

max

 K maxo  0 1  hc 

(1.5eV)(230 10 1.2410

6

9

m)

eV m

1

 

180 nm.



Inha University

Department of Physics

13. What is the maximum wavelength of light that will cause photoelectrons to be emitted from sodium? What will the maximum kinetic energy of the photoelectrons be if 200-nm light falls on a sodium surface? Sol The maximum wavelength would correspond to the least energy that would allow an electron to be emitted, so the incident energy would be equal to the work function, and 6

max hc 1.24 10 eV m  539 nm  2.3 eV where the value of  for sodium is taken from Table 2.1. From Equation (2.8),

Kmax h

hc 

6



1.2410 eVm 2.3 eV 3.9 eV. 9 20010 m

15.

1.5 mW of 400-nm light is directed at a photoelectric cell. If 0.10 percent of the incident photons produce photoelectrons, find the current in the cell. Sol Because only 0.10% of the light creates photoelectrons, the available power is (1.0x10-3)(1.5x10-3W) = 1.5x10-6 W. the current will be the product of the number of photoelectrons per unit time and the electron charge, or P

P P I e e e (1e) E hc/hc

Inha University

(1.5 10

6

J/s)(400 10

1.24 10-6 eV m

9

m)

0.48 A

Department of Physics

17. A metal surface illuminated by 8.5 x 10 14 Hz light emits electrons whose maximum energy is 0.52 eV The same surface illuminated by 12.0 x 10 14 Hz light emits electrons whose maximum energy is 1.97 eV From these data find Planck's constant and the work function of the surface . Sol Denoting the two energies and frequencies with subscripts 1 and 2, Kmax,1 h1, K max,2 h2  Subtracting to eliminate the work function  and dividing by 1 -2, K max,2 K max,1 19.7eV 0.52eV 15 h  4.110 eV s  14 14 10 Hz 8.5 10 Hz 2 1 12.0 to the allowed two significant figures. Keeping an extra figure gives 15

-34

h  4.14 10 eV s 6.6410 Js The work function  may be obtained by substituting the above result into either of the above expressions relating the frequencies and the energies, yielding  = 3.0 eV to the same two significant figures, or the equations may be solved by rewriting them as K max,21  h1 1 , Kmax,12  h12 2, subtracting to eliminate the product h12 and dividing by 1 -2 to obtain



K max,2 1 Kmax,12 2 1

14



(19.7 eV)(8.510 Hz) 14

(12.010

14

(0.52 eV)(12.010 Hz) Hz  .8510

14

3.0 eV

Hz)

(This last calculation, while possibly more cumbersome than direct substitution, reflects the result of solving the system of equations using a symbolic-manipulation program; using such a program for this problem is, of course, a case of "swatting a fly with a sledgehammer".)

Inha University

Department of Physics

19. Show that it is impossible for a photon to give up all its energy and momentum to a free electron. This is the reason why the photoelectric effect can take place only when photons strike bound electrons. Sol Consider the proposed interaction in the frame of the electron initially at rest. The photon's initial momentum is po = Eo/c, and if the electron were to attain all of the photon's momentum and energy, the final momentum of the electron must be pe = po = p, the final electron kinetic energy must be KE = Eo = pc, and so the final electron energy is Ee = pc + mec2. However, for any electron we must have Ee2 = (pc)2 + (mec2)2. Equating the two expressions for Ee2 2 Ee

2 2

2 2

(pc)  mec

or

2

  pc mec (pc) 0 2(pc mec2 

2

2(pc mec

2

2 2

mec,

This is only possible if p = 0, in which case the photon had no initial momentum and no initial energy, and hence could not have existed. To see the same result without using as much algebra, the electron's final kinetic energy is 2 4

2

p2c2 m for nonzero p. An easier alternative is to consider the interaction in the frame where the electron is at rest after absorbing the photon. In this frame, the final energy is the rest energy of the electron, c , but before the interaction, the electron would have been moving (to conserve momentum), and m e 2 hence would have had more energy than after the interaction, and the photon would have had positive energy, so energy could not be conserved.

Inha University

Department of Physics

21. Electrons are accelerated in television tubes through potential differences of about 10 kV. Find the highest frequency of the electromagnetic waves emitted when these electrons strike the screen of the tube. What kind of waves are these? Sol For the highest frequency, the electrons will acquire all of their kinetic energy from the accelerating voltage, and this energy will appear as the electromagnetic radiation emitted when these electrons strike the screen. The frequency of this radiation will be E eV (1e )(10 103 V) 18    15 2.4 10 Hz h h 4.1410 eV s which corresponds to x-rays. 23. The distance between adjacent atomic planes in calcite (CaCO 3) is 0.300 nm. Find the smallest angle of Bragg scattering for 0.030-nm x-rays. Sol Solving Equation (2.13) for  with n = 1,    0.030 nm  o  arcsin  arcsin  .29 2d  20.300 nm   

Inha University

Department of Physics

25. What is the frequency of an x-ray photon whose momentum is 1.1 x 10-23 kg m/s? Sol From Equation (2.15), -23

kg m/s) 18  cp ( .30 108 m/s)(1.110  34 5.0 10 Hz h 6.6310 Js 27. In See. 2.7 the x-rays scattered by a crystal were assumed to undergo no change in wavelength. Show that this assumption is reasonable by calculating the Compton wavelength of a Na atom and comparing it with the typical x-ray wavelength of 0.1 nm. Sol Following the steps that led to Equation (2.22), but with a sodium atom instead of an electron,

C,



Na -8

h

cMNa

34



6.6310

Js

(3.0108 m/s)(3.8210

5.810

-26

17

m,

kg)

or 5.8 x 10 nm, which is much less than o.1 nm. (Here, the rest mass MNa =3.82 x 10-26 kg was taken from Problem 2-24.)

Inha University

Department of Physics

29. A beam of x-rays is scattered by a target. At 45o from the beam direction the scattered x-rays have a wavelength of 2.2 pm. What is the wavelength of the x-rays in the direct beam? Sol Solving Equation (2.23) for , the wavelength of the x-rays in the direct beam,

C(1 cos)2.2 pm(2.426 pm)(1cos45o)1.5 pm to the given two significant figures. 31. An x-ray photon of initial frequency 3.0 x 1019 Hz collides with an electron and is scattered through 90o. Find its new frequency. Sol Rewriting Equation (2.23) in terms of frequencies, with  = c/ and ’ = c/’ , and with cos 90o = 0, c c  C   and solving for ’ gives 1

12

1

m 19 1 C   1 2.4310        2.410 Hz 19    3.0 10 8 m/s  c  3.0 10 Hz The above method avoids the intermediate calculation of wavelengths.

Inha University

Department of Physics

33.

At what scattering angle will incident 100-keV x-rays leave a target with an energy of 90 keV?

Sol Solving Equation (2.23) for cos,

cos1

 

C





C

mc 2 mc 2  511 keV 511 keV 1  0.432  1  E E 100 keV 90 keV   

from which  = 64 to two significant figures. 35. A photon of frequency  is scattered by an electron initially at rest. Verify that the maximum kinetic energy of the recoil electron is KEmax = (2h2 2/mc2)/(1 + 2h/mc2). Sol For the electron to have the maximum recoil energy, the scattering angle must be 180 0, and Equation (2.20) becomes mc2 KEmax = 2 (hv) (hv'), where KEmax = (hv - hv') has been used. To simplify the algebra somewhat, consider        ,  1(/) 1(2C /) 1(2C /c) where  = 2C for  = 180o. With this expression, o

2

2

2(h) /(mc ) KEmax  2(h)(h) 2  mc 1(2C /c) Using C = h/(mc) (which is Equation (2.22)) gives the desired result.

Inha University

Department of Physics

37. A photon whose energy equals the rest energy of the electron undergoes a Compton collision with an electron. If the electron moves off at an angle of 40o with the original photon direction, what is the energy of the scattered photon? Sol As presented in the text, the energy of the scattered photon is known in terms of the scattered angle, not the recoil angle of the scattering electron. Consider the expression for the recoil angle as given preceding the solution to Problem 2-25: sin sin sin tan   (/) (1cos) ( /)(1cos) (1 cos)  C  C 1 (1cos)    2 For the given problem, with E = mc ,  = hc/E = h/(mc) = C, so the above expression reduces to

tan

sin 2(1cos)

At this point, there are many ways to proceed; a numerical solution with  = 40o gives  = 61.60 to three significant figures. For an analytic solution which avoids the intermediate calculation of the scattering angle , one method is to square both sides of the above relation and use the trigonometric identity sin2 = 1 - cos2 = (1 + cos)(1 - cos) to obtain 1 cos 2 4tan   cos 1 (the factor 1 - cos may be divided, as cos = 1,  = 0, represents an undeflected photon, and hence no interaction). This may be re-expressed as

Inha University

Department of Physics

     2

(1  cos)(4 tan

)1 cos 2 (1 cos), 2

2 1cos

or

2

1 4tan 

,

2 cos

34tan  2

14tan 

Then with ’ =  + C(1 - cos) = C(2 - cos), 2 2 o EE  E 14tan  (511 keV) 1 4tan (40 ) 335 eV  34tan 2  3 2 o 4tan (40 ) An equivalent but slightly more cumbersome method is to use the trigonometric identities sin 2sin cos  , 1 cos2sin 2 2 2 2 in the expression for tan  to obtain 1   1  tan cot , 2arctan   2 2 2tan o yielding the result  = 61.6 more readily.

Inha University

Department of Physics

39. A positron collides head on with an electron and both are annihilated. Each particle had a kinetic energy of 1.00 MeV Find the wavelength of the resulting photons. Sol The energy of each photon will he the sum of one particle's rest and kinetic energies, 1.511 MeV (keeping an extra significant figure). The wavelength of each photon will be hc 1.24 106 eV m 13   8.2110 m 0.821 pm E 1.51106 eV 41. Show that, regardless of its initial energy, a photon cannot undergo Compton scattering through an angle of more than 60o and still be able to produce an electron-positron pair. (Hint: Start by expressing the Compton wavelength of the electron in terms of the maximum photon wavelength needed for pair production.) Sol Following the hint, h 2hc 2hc C  2  , mc 2mc E min where Emin = 2mc2 is the minimum photon energy needed for pair production. The scattered wavelength (a maximum) corresponding to this minimum energy is ’max = (h/Emin), so C = 2’max . At this point, it is possible to say that for the most energetic incoming photons,  ~ 0, and so 1 - cos= ½ for  ' = C /2, from which cos = ½ and  = 60o. As an alternative, the angle at which the scattered photons will have wavelength ’max can m be found as a function of the incoming photon energy E; solving Equation (2.23) with  ' = 'max)

Inha University

Department of Physics

     

max





max

hc/E 1 mc 2    C 2 E

1 C  C 2 This expression shows that for E >> mc , cos = ½ and so  = 60o, but it also shows that, because cos must always be less than 1, for pair production at any angle, E must be greater than 2mc2, which we know to be the case. cos1

43.

(a) Show that the thickness x1/2, of an absorber required to reduce the intensity of a beam of radiation by a factor of 2 is given by x1/2 = 0.693/. (b) Find the absorber thickness needed to produce an intensity reduction of a factor of 10.

Sol (a) The most direct way to get this result is to use Equation (2.26) with Io/I = 2, so that ln2 0 693 I  Ioe x x 1/2     (b) Similarly, with Io/I = 10,

x

1/10

ln10 



2 30 

  

Inha University

Department of Physics

45. The linear absorption coefficient for 1-MeV gamma rays in lead is 78 m-1. find the thickness of lead required to reduce by half the intensity of a beam of such gamma rays. Sol From either Equation (2.26) or Problem 2-43 above, ln2 0.693 x 1/2   -1 8.9 mm  78 m 47. The linear absorption coefficients for 2.0-MeV gamma rays are 4.9 m-1 in water and 52 in -1 in lead. What thickness of water would give the same shielding for such gamma rays as 10 mm of lead? Sol Rather than calculating the actual intensity ratios, Equation (2.26) indicates that the ratios will be the same when the distances in water and lead are related by H2O xH2O Pb xPb, or xH2O xPb

Pb H2O

-1

(10 10

3

m)

52 m 4.9m

-1

 0.106 m

or 11 cm two significant figures.

Inha University

Department of Physics

49. What thickness of copper is needed to reduce the intensity of the beam in Exercise 48 by half. Sol Either a direct application of Equation (2.26) or use of the result of Problem 2-43 gives ln 2 5 x  1.47 10 m, 1/2 -1 4.7 104 m which is 0.015 mm to two significant figures. 51. The sun's mass is 2.0 x 1030 kg and its radius is 7.0 x 108 m. Find the approximate gravitational red shift in light of wavelength 500 nm emitted by the sun. Sol In Equation (2.29), the ratio 11 2 30 kg) 6 (6.67 10 Nm /kg)(2.010  2.1210 2 8 2 4 -1 cR (3.010 m/s) (7.0 10 m )

GM

(keeping an extra significant figure) is so small that for an “approximate” red shift, the ratio / will be the same as /, and 

GM 2

c R

Inha University

(500 10

9

-6

m)(2.12 10 ) 1.06 10

-12

m 1.06 pm.

Department of Physics

53.

As discussed in Chap. 12, certain atomic nuclei emit photons in undergoing transitions from "excited" energy states to their “ground” or normal states. These photons constitute gamma rays. When a nucleus emits a photon, it recoils in the opposite direction. (a) The decays by K capture to

57 26

57 27 Co

nucleus

Fe , which then emits a photon in losing 14.4 keV to reach its ground

57 26 Fe

state. The mass of a atom is 9.5 x 10-26 kg. By how much is the photon energy reduced from the full 14.4 keV available as a result of having to share energy and momentum with the recoiling atom? (b) In certain crystals the atoms are so tightly bound that the entire crystal recoils when a gamma-ray photon is emitted, instead of the individual atom. This phenomenon is known as the Mössbauer effect. By how much is the photon energy reduced in this situation if the ex- cited 2576Fe nucleus is part of a 1.0-g crystal? (c) The essentially recoil-free emission of gamma rays in situations like that of b means that it is possible to construct a source of virtually monoenergetic and hence monochromatic photons. Such a source was used in the experiment described in See. 2.9. What is the original frequency and the change in frequency of a 14.4-keV gamma-ray photon after it has fallen 20 m near the earth's surface? Sol (a) The most convenient way to do this problem, for computational purposes, is to realize that the nucleus will be moving nonrelativistically after the emission of the photon, and that the energy of the photon will be very close to E = 14.4 keV, the energy that the photon would have if the nucleus had been infinitely massive. So, if the photon has an energy E, the recoil momentum of the nucleus 2

2

2

is E/c, and its kinetic energy is p /2M E /(2Mc ), here M is the rest mass of the nucleus. Then, conservation of energy implies

Inha University

Department of Physics

2

E 2 EE 2Mc This is a quadratic in E, and solution might be attempted by standard methods, but to find the change in energy due to the finite mass of the nucleus, and recognizing that E will be very close to E, the above relation may be expressed as E  E 

E

2

2Mc

2

2



E

2  2Mc

16

2

 (14.4 keV) (1.60 10 J/keV) 1.9106 keV 1.9 103eV. -26 2 2(9.510 kg)(3.0 108 m/s) If the approximation E E, is not made, the resulting quadratic is 2

2

2

E 2Mc E 2Mc E0, which is solved for E  Mc 2 12 E 1   2 Mc   2 However, the dimensionless quantity E/(Mc ) is so small that standard calculators are not able to determine the difference between E and E. The square root must be expanded, using (1 + x)1/2 1 + (x/2) - (x2/8), and two terms must be kept to find the difference between E and E. This approximation gives the previous result.

Inha University

Department of Physics

It so happens that a relativistic treatment of the recoiling nucleus gives the same numerical result, but without intermediate approximations or solution of a quadratic equation. The relativistic form expressing conservation of energy is, with pc = E and before, 2

2

E2 (Mc2) EMc2 E,

E2(Mc2)  Mc2 E 

or

E.

Squaring both sides, canceling E2 and (Mc2)2, and then solving for E, 2

2

E  2Mc E

E 

2



2

From this form,

1(E /(2Mc ))  E    2  E) 1(E/(Mc )) 

2(Mc   2  EE  E 1   , giving the same result.  2  2 2Mc 1E /(Mc ) (b) For this situation, the above result applies, but the nonrelativistic approximation is by far the easiest for calculation;

E E 

2

E



2

2



(14.4 103eV) (1.610

2Mc (c) The original frequency is

19

J/eV)

-3

h

25

eV.

2

2(1.010 kg)(3.0108m/s) E  14.4103eV 

1.810



4.1410

15

eVs

18

3.4810 Hz.

From Equation (2.28), the change in frequency is 2

18  gH  (9.8m/s )(20m)   ( .48 10 Hz) 7.6 Hz.

2

c 

Inha University

8

(3.0 10 m/s)

2

Department of Physics

55. The gravitational potential energy U relative to infinity of a body of mass m at a distance R from the center of a body of mass M is U = -GmM/R. (a) If R is the radius of the body of mass M, find the escape speed v, of the body, which is the minimum speed needed to leave it permanently. (b) Obtain a formula for the Schwarzschild radius of the body by setting vc = c, the speed of light, and solving for R. (Of course, a relativistic calculation is correct here, but it is interesting to see what a classical calculation produces.) Sol (a) To leave the body of mass M permanently, the body of mass m must have enough kinetic energy so that there is no radius at which its energy is positive. That is, its total energy must be nonnegative. The escape velocity ve is the speed (for a given radius, and assuming M >> m) that the body of mass m would have for a total energy of zero; 1 GMm 2GM 2mve 0, or v e  2 R R 

(b) Solving the above expression for R in terms of ve, R and if ve = c, Equation (2.30) is obtained.

Inha University

2GM 2 ve

,

Department of Physics

Chapter 3. Problem Solutions 1.

A photon and a particle have the same wavelength. Can anything be said about how their linear momenta compare? About how the photon's energy compares with the particle's total energy? About how the photon’s energy compares with the particle's kinetic energy?

Sol From Equation (3.1), any particle’s wavelength is determined by its momentum, and hence particles with the same wavelength have the same momenta. With a common momentum p, the photon’s 2

energy is pc, and the particle’s energy is ( pc )  (mc )2 , which is necessarily greater than pc for a massive particle. The particle’s kinetic energy is 2 2

KEmc  pc  mc   mc For low values of p (p (mc2)2, then pc >> mc2 and E pc. For a photon with the same energy, E = pc, so the momentum of such a particle would be nearly the same as a photon with the same energy, and so the de Broglie wavelengths would be the same.

Inha University

Department of Physics

Chapter 3. Problem Solutions 13. An electron and a proton have the same velocity Compare the wavelengths and the phase and group velocities of their de Broglie waves. Sol For massive particles of the same speed, relativistic or nonrelativistic, the momentum will be proportional to the mass, and so the de Broglie wavelength will be inversely proportional to the mass; the electron will have the longer wavelength by a factor of (mp/me) = 1838. From Equation (3.3) the particles have the same phase velocity and from Equation (3.16) they have the same group velocity. 15. Verify the statement in the text that, if the phase velocity is the same for all wavelengths of a certain wave phenomenon (that is, there is no dispersion), the group and phase velocities are the same. Sol Suppose that the phase velocity is independent of wavelength, and hence independent of the wave number k; then, from Equation (3.3), the phase velocity vp = (/k) = u, a constant. It follows that because  = uk, d v g  u v p dk

Inha University

Department of Physics

Chapter 3. Problem Solutions 17. The phase velocity of ocean waves is g/2 , where g is the acceleration of gravity. Find the group velocity of ocean waves Sol The phase velocity may be expressed in terms of the wave number k = 2/ as  g vp  , or   gk or 2 gk. k k Finding the group velocity by differentiating (k) with respect to k,

v  g

1 1 1 g 1  1  g    v p dk 2 k 2 2 k 2k 2

d

Using implicit differentiation in the formula for  (k), d 2  2vgg, dk v g 

g

gk

2





1

    vp, 2 2k 2k 2k 2 the same result. For those more comfortable with calculus, the dispersion relation may be expressed as so that

2ln() ln(k) ln(g), from which

2

ddk  , and  k

Inha University

v g 

1 

1  v p 2k 2

Department of Physics

Chapter 3. Problem Solutions 19. Find the phase and group velocities of the de Broglie waves of an electron whose kinetic energy is 500 keV. 2 Sol 500 511 1 K mc For a kinetic energy of 500 keV, 1 978     511 2 2 2 1v /c mc Solving for v, v c 1(1/ )2 c 1(1/1.978) 20.863c, and from Equation (3.16), vg = v = 0.863c. The phase velocity is then vp = c2 /vg = 1.16 c.

21.

(a) Show that the phase velocity of the de Broglie waves of a particle of mass m and de Broglie wavelength  is given by 2

mc vp c 1   h 

(b) Compare the phase and group velocities of an electron whose de Broglie wavelength is -13 exactly 1 x 10 m. Sol (a) Two equivalent methods will be presented here. Both will assume the validity of Equation (3.16), in that vg = v. First: Express the wavelength x in terms of vg, h

h   1 p mv   mv g

Inha University

2

h

g

vg 2

c

Department of Physics

Multiplying by mvg, squaring and solving for vg2 gives 2

2 1

mc    c 1  2 2 2 (m) (h /c )   h   Taking the square root and using Equation (3.3), vp = c2/vg, gives the desired result. h

2 vg

2 

Second: Consider the particle energy in terms of vp = c2 lvg; 2

E (pc) mc 2



2

22

 22 

22

mc mc 

2 2

1c

Dividing by (mc ) leads to c2 1 2   vp

c

2

2 vp

1

2

/v

2 p

 

1 2

2

1h /(mc)

1 2

2

hc  2 2.   mc

1h /(mc)

2



h

,

so that

2 (mc)

2

1

 2 h (mc) 1 1(mc) /h 2

2

2

,

which is an equivalent statement of the desired result. It should be noted that in the first method presented above could be used to find  in terms of vp directly, and in the second method the energy could be found in terms of vg. The final result is, or course, the same.

Inha University

Department of Physics

(b) Using the result of part (a), 31

kg)(3.0 108 m/s)(1.0 10 vpc 1 (9110   34  6 6310 Js and vg = c2/vp = 0.99915c. For a calculational shortcut, write the result of part (a) as 2

-13

2

m) 1  

00085c,

2

-13  (511103eV)(1.00 10 m) vp c 1 mc c 1  1 00085c   6   hc 1 2410 eV m     In both of the above answers, the statement that the de Broglie wavelength is “exactly” 10 -13 m means that the answers can be given to any desired precision. 2

23. What effect on the scattering angle in the Davisson-Germer experiment does increasing the electron energy have? Sol Increasing the electron energy increases the electron's momentum, and hence decreases the electron's de Broglie wavelength. From Equation (2.13), a smaller de Broglie wavelength results in a smaller scattering angle.

Inha University

Department of Physics

Chapter 3. Problem Solutions 25. In Sec. 3.5 it was mentioned that the energy of an electron entering a crystal increase, which reduces its de Broglie wavelength. Consider a beam of 54-eV electrons directed at a nickel target. The potential energy of an electron that enters the target changes by 26 eV. (a) Compare the electron speeds outside and inside the target. (b) Compare the respective de Broglie wavelengths. Sol (a) For the given energies, a nonrelativistic calculation is sufficient; v 

2K



2(54 eV)(1.60 10

-19

J/eV)

4.36 m/s m 9.110 kg outside the crystal, and (from a similar calculation, with K = 80 eV), v = 5.30 x 106 m/s inside the crystal (keeping an extra significant figure in both calculations). (b) With the speeds found in part (a), the de Brogile wavelengths are found from 31

34

10 h 6.6310 Js  h 1.6710 m,   p mv ( .111031 kg)(4.36 106 m/s) or 0.167 nm outside the crystal, with a similar calculation giving 0.137 nm inside the crystal.

Inha University

Department of Physics

Chapter 3. Problem Solutions 27. Obtain an expression for the energy levels (in MeV) of a neutron confined to a one-dimensional box 1.00 x 10-14 m wide. What is the neutron's minimum energy? (The diameter of an atomic nucleus is of this order of magnitude.) Sol From Equation (3.18), En n

h

2

2

8mL

n

2

2

(6.63 10 27

34

Js)

2

2

-14

m) 8(1.67 10 kg)(1.00 10 The minimum energy, corresponding to n = 1, is 20.5 MeV

2

n 3.2810

13

2

J n 20.5 MeV.

29. A proton in a one-dimensional box has an energy of 400 keV in its first excited state. How wide is the box? Sol The first excited state corresponds to n = 2 in Equation (3.18). Solving for the width L,  

L 

n

h

2

8mE 2

2

8(1.6710

27

(6.6310

34

Js)

2

kg)(400 103 eV)(1.60 10

-19

J/eV)

 4.5310 14 m 45.3 fm.

Inha University

Department of Physics

Chapter 3. Problem Solutions 31. The atoms in a solid possess a certain minimum zero-point energy even at 0 K, while no such restriction holds for the molecules in an ideal gas. Use the uncertainty principle to explain these statements. Sol Each atom in a solid is limited to a certain definite region of space - otherwise the assembly of atoms would not be a solid. The uncertainty in position of each atom is therefore finite, and its momentum and hence energy cannot be zero. The position of an ideal-gas molecule is not restricted, so the uncertainty in its position is effectively infinite and its momentum and hence energy can be zero. 33. The position and momentum of a 1.00-keV electron are simultaneously determined. If its position is located to within 0.100 nm, what is the percentage of uncertainty in its momentum? Sol The percentage uncertainty in the electron's momentum will be at least h h hc p    p 4px 4x 2mK 4x 2(mc)2 K  



(1.24 10

10

6

eV m)

3.110

2

3.1 %.

4(1.00 10 m) 2(511103 eV)(1.00 103eV) Note that in the above calculation, conversion of the mass of the electron into its energy equivalent in electronvolts is purely optional; converting the kinetic energy into joules and using h = 6.626 x 10-34 J·s will of course give the same percentage uncertainty.

Inha University

Department of Physics

Chapter 3. Problem Solutions 35. How accurately can the position of a proton with v